JP4407957B2 - Interlocking device for use with an aircraft emergency evacuation system - Google Patents

Description

  The present invention relates generally to a mechanism for preparing, releasing, and activating an emergency system, and more particularly, to preparing, releasing, and activating an emergency evacuation system for a commercial passenger aircraft. Regarding the mechanism.

  Commercial passenger aircraft often include emergency evacuation systems with inflatable slides for use with commercial or passenger entrance doors. Generally, the slide is connected to the inside of the door in a folded, contracted form. Before the plane takes off, the crew prepares the slide evacuation system for operation. When the system is ready for operation, the base of the slide is secured to the fuselage of the airplane under the door. In a system ready for operation, the evacuation system is activated when the door associated with the slide opens. When activated, the system uses one or more pneumatic reservoirs of pressurized gas to help the door open and widen and expand the slide. When the crew releases the system, the base of the slide is secured to the door. Thus, when the door opens, the slide base moves with the door and the system does not start.

  This emergency slide evacuation system has three main problems. First, after normal flight and landing, the crew may open the door without releasing the system. This causes the slide to expand and swell, resulting in airline embarrassment and financial expense.

  Second, when the door is open, the crew may unintentionally put the system in a ready state for operation. This will release the base of the slide. Although not as dramatic as an unintentionally activated slide, this also creates a financial expense for the airline because the crew has to re-fasten the slide to make the plane operational again.

  Third, the mechanism for activating the emergency slide evacuation system relies on mechanical linkage to penetrate the partition in the pneumatic gas pressure reservoir to activate the evacuation system. This mechanical linkage is complex and expensive to manufacture and maintain, and can be unreliable if not correctly installed and / or maintained.

  Attempts have been made to solve some of these problems. For example, Japanese Patent No. 3,157,297 provides a mechanism for putting an aircraft slide evacuation system into a ready state and releasing it, including an interlock that prevents the door from being ready when the door is open. Teaching. Thus, the crew cannot unlock the slide from the door while the door is open. However, this interlock mechanism is unnecessarily complex and expensive to manufacture and install.

  The present invention provides an improved solution to the aforementioned problems.

The present invention provides a mechanism for preparing, releasing and activating an aircraft emergency evacuation system. An emergency evacuation system using the present invention includes an escape slide and a pneumatic reservoir containing pressurized gas sealed behind a divider for activating the emergency evacuation system. The slide includes a mooring bar connected to one end of the slide. When the evacuation system is ready for operation, the mooring bar is secured to the fuselage of the airplane under the door. If the door is opened when the evacuation system is ready for operation, the system will be activated to expand and expand the slide. When the system is released, the mooring bar is fixed to the bottom of the door and the emergency evacuation system is not activated when the door is opened.

  The invention includes a pair of floor fittings installed on each side of the door on the floor of the airplane. Each floor fixture includes a notch for receiving a mooring bar. The pawls included in each floor fixture are positioned where the mooring bar can be pulled out of the notch and secured to the lower edge of the door from the position where it holds the mooring bar in the notch (system ready). It is possible to rotate to release.

  Further included in this invention is a pair of support fixtures installed on the airplane door for engagement with the floor fixture when the door is closed and locked. Each support fixture includes a first jaw that extends downwardly. When the door is closed and locked, this jaw surrounds the inboard portion of the end region of the mooring bar.

  Each of the support fixtures further includes a second downwardly extending jaw that can be rotated to partially surround the outboard portion of the end region of the mooring bar. The rotation of the second jaw to engage the mooring rod is done by releasing the evacuation system and rotating the handle located on the door. As the second jaw rotates to a position that surrounds the mooring bar, the pawls of each flooring fixture will move from the notch of the flooring fixture as the door moves toward its open state. Rotate further to the position where it comes off The interlocking device is incorporated into a linkage that operates the second jaw and prevents the second jaw from rotating in a direction that releases the anchor rod, thereby preventing the second jaw from rotating between the jaw and the support fixture. Ensure continued anchoring of the mooring rod (and hence to the door). This interlocking feature prevents accidental release or dropping of the mooring bar due to careless operation of the evacuation system.

  When the handle that puts and releases the emergency evacuation system into the ready state is rotated, the second jaw is in a position that does not partially surround the end region of the mooring bar. The mooring rod rotates and is held in the recess of the floor fixture by the pawl of the floor fixture. If the door is opened while the system is ready for operation, the escape slide is automatically deployed.

  The presently preferred embodiment of the present invention includes a configuration for reliably activating the emergency evacuation system. Included in this activation configuration is a blast tube attached to a pneumatic reservoir that moves the door to its open position. A battery or other power source is connected to the squib through two series connected switches. The first switch is closed when the handle to put the system in a ready state and release is in a ready state. When the inner door handle is moved to its open position, the second switch closes. Thus, when the door is opened with the system ready for operation, current flows through the squib, which moves through the divider and moves the door open by the first pneumatic reservoir, and then the second Inflate the slide with a pneumatic reservoir.

  The invention further includes a flag that visually indicates that the emergency evacuation system is ready for operation. This flag extends from the pawl of the floor fitting and moves from the first position to the second position when the pawl rotates from the locked position to the unlocked position. When the pawl is in the locked position (the mooring bar is secured by the floor fixture), the clear colored area (or other indication) of the flag can be easily recognized.

Many of the foregoing aspects and attendant advantages of the present invention will become more readily appreciated when it is better understood by reference to the following detailed description, taken in conjunction with the accompanying drawings, in which:

  FIG. 1 shows a preferred embodiment of a mechanism 10 according to the present invention that is attached to an aircraft business or passenger entrance door 14. The mechanism 10 prepares and releases the emergency slide evacuation system that can be deployed to quickly exit the airplane through the door 12. The evacuation system (not shown in FIG. 1) includes an inflatable slide housed in a collapsed and folded configuration within a container that is secured to the inner surface of the door 14. The base of the slide extends from the lower end of the container. When the mechanism 10 prepares the system for operation, the base of the slide is secured to the aircraft fuselage 12 under the door 14. When the door 14 is opened when the system is ready for operation, the system expands and expands the slide.

  In FIG. 1, the end of the slide is fixed to a mooring bar 16 located at the bottom of the door 14. The mechanism 10 connects the mooring bar 16 to the airplane fuselage 12 under the door 14 to prepare the system for operation. Therefore, when the evacuation system activates the slide, the base of the slide is fixed to the body below the door 14, and the slide expands and expands. To release the system, mechanism 10 connects mooring bar 16 to door 14. Therefore, when the door 14 opens, the slide moves with the door.

  The mechanism 10 includes a floor fixture 18 attached to the opposite end of the door 14 for receiving the end of the mooring bar 16 when it is ready to operate the slide evacuation system. Each floor fixture 18 is detachably engaged with a corresponding support fixture 20 attached to the lowermost portion of the door 14. When the evacuation system is released, the support fixture 20 fixes the end of the mooring bar to the door 14.

  When the door 14 is closed and locked, the door 14 aligns the support fixture 20 with the floor fixture 18 and engages the support fixture with the floor fixture. Specifically, the door 14 of FIG. 1 is a business or passenger entrance door of the type that moves upward relative to the aircraft fuselage when its latch is released or unlocked. The door then swings outward to open the entrance to the airplane. When the door 14 is closed, the door 14 swings inward and then moves downward relative to the fuselage 12 to latch the door or lock the door. Thus, when the door 14 is closed, each support fixture 20 is vertically aligned with its associated floor fixture 18. Further, when the door 14 is locked, the support fixture 20 moves downward (together with the door) for engagement with the floor fixture 18. The crew member locks and unlocks the door 14 by rotating the door handle 21 inside the door 14 from the first position to the second position.

  As shown in FIG. 1, the torque tube 22 extends between the support fixtures 20. During the evacuation system operation preparation sequence, the torque tube 22 rotates in one direction so that the support fixture 20 releases the mooring bar 16. During the evacuation system release sequence, the torque tube 22 rotates in the other direction so as to grasp the mooring bar 16. In order to rotate the torque tube 22 in the required direction, a handle 24 attached to the inside of the door 14 is operated between a first position and a second position. A push-pull cable 26 connects the handle 24 to the torque tube 22 at the bottom of the door 14 to transmit torque from the handle to the torque tube. The bush pull cable 26 is of the type having a relatively stiff outer sheath that allows it to transmit axial force between the handle 24 and the torque tube 22. As handle 24 rotates and then torque tube 22 rotates, the cable slidably mounted in the armor is extended upward and downward. Alternatively, the torque from the handle 24 can be transmitted to the torque tube 22 using a conventional linkage rod or other structure such as a non-limiting illustrative pulley system.

  Referring to FIG. 2, the mooring bar 16 includes an intermediate portion 28 that is substantially rectangular in cross-sectional profile. A cylindrical end portion 30 extends from each end of the intermediate portion 28 along a common axis that is generally parallel to the longitudinal axis of the intermediate portion 28.

  Each floor fixture 18 includes a base 32 for attachment to the aircraft fuselage 12. Preferably, the base 32 includes a horizontally extending flange 34 through which a bolt 36 (or another type of through fastener) extends to attach it to the fuselage 12. The base 32 can be adjusted upward and downward by inserting or removing shims (not shown) between it and the aircraft fuselage 12. In addition, the position of the base 32 toward the inside and outside of the machine, that is, the position of the base in the direction toward or away from the door, is a saw tooth plate (not shown) inserted between the base and the fuselage 12. To adjust. The sawtooth notches on the plate are selectively meshed with the sawtooth notches formed on the bottom of the base 32 to adjust the inboard and outboard positions of the base.

  Referring to FIG. 4, the notch-shaped recess 40 is located in the central region of each base 32. The recess 40 does not face the door 14 and is positioned to receive the cylindrical end portion 30 of the mooring bar 16. A generally flat, smooth surface portion 38 that slopes downwardly away from the door 14 forms the lower side of the notch 40. The end of the notch 40 facing the intermediate portion of the mooring bar 16 is open so that the cylindrical portion 30 of the mooring bar can extend into the notch 40 in the manner illustrated in FIG. Opposing ends of the notch 40 are terminated by a wall 44 extending upward and outward. The second wall portion 44 extends along the opposite side surface of the base 32.

  Located between the walls 44 is a diamond-shaped pawl 42 that is mounted for rotation about the pin 46. As the end of the pawl 42 closer to the notch 40 rotates to its lowest or unlocked position, the cylindrical end portion 30 of the mooring bar 16 can move into or withdraw from the notch 40 ( 3 and 4). When the end of the pawl 42 is in its uppermost rotational or locked position, the cylindrical portion 30 of the mooring bar is captured and retained in the notch 40 (FIGS. 5 and 6). The pawl 42 has a center of gravity that holds it in the locked position. In addition, a torsion spring (not shown) surrounds the periphery of the pin 46 to bias the pawl 42 to the locked position. Thus, when the cylindrical portion 30 of the mooring bar 16 is positioned in the notch 40, the pawl 42 locks the mooring bar to the floor fixture 18.

  A flag 48 is attached to the end of the pawl 42 opposite the notch 40. The flag includes a generally L-shaped bracket 50 with one leg attached to the pawl 42. The other leg extends upward. A generally V-shaped plate 52 having one leg longer than the other leg is attached to the lateral leg of the L-shaped bracket 50. The long leg portion of the V-shaped plate 52 is attached to the leg portion that extends above the L-shaped plate 50 with the V-shaped plate opened downward. The bracket 50 and the plate 52 may be connected to each other by any method known in the art, such as using a through-type fastener, welding, soldering, an adhesive, or the like. As will be discussed in more detail later, preferably at least some portion of flag 48 is painted with an easily eye-catching color, such as yellow, orange, or red.

  The portion of the base 32 of the floor fixture 18 that is closest to the door 14 includes a finger-like protrusion 54 that extends upwardly toward the door 14. As will be described in more detail later, the finger 54 activates the interlocking device on the support fixture 20 when the door 14 is closed.

As best seen in FIG. 2, the support fixture 20 includes a base plate 56 that is attachable to the door 14. Extending downward from the base plate 56 is a jaw 58. As shown in FIG. 5, when the door 14 is closed and locked, the rounded inner edge 59 of the jaw 58 partially surrounds the cylindrical end portion of the anchor bar 16. The jaw 58 is positioned between the walls 44 of the floor fixture 18.

  As further seen in FIG. 2, the first linkage member or grooved bell crank 60 is rotatably mounted on a vertically extending flat surface 57 of the base plate 56. More specifically, a pin or axle 62 that is press fit or otherwise connected to bell crank 60 passes through a suitably sized opening in base plate 56 and torque tube 22. Connect to one end of Rotation of the torque tube 22 that is substantially parallel to the centerline of the shaft of the mooring bar 16 then rotates the axle 62 and causes the bell crank 60 to rotate.

  At one end of the bell crank 60 is a connecting arm 64 that extends away from the axle 62 in a direction that generally points away from the door 14. At the far end of the connecting arm 64 is a groove 68 having a rounded end region. The longitudinal axis of the groove 68 substantially coincides with the longitudinal axis of the connecting arm 64.

  At the opposite end of the bell crank 60 is an interlocking arm 66 extending downward from the axle 62 so as to form an obtuse angle with the connecting arm 64. The far end of the interlocking arm 66 forms a dovetail shape.

  The second linkage member 70 is rotatably attached to the flat surface 57 at a position below the bell crank 60 and closer to the interior of the machine. More specifically, the bottom inboard portion of each base plate 56 is configured to form two spaced, substantially parallel flange regions 76 and 78 that extend downwardly toward the floor of the aircraft.

  Extending upward between the flanges 76 and 78 is the first arm 80 of the second linkage member 70. The pin or axle 82 is aligned with the openings in the flanges 76 and 78 so that the second linkage member 70 (ie, the first arm 80) can rotate about an axis that is generally parallel to the longitudinal axis of the mooring bar 16. Part and the opening of the first arm of the second linking member 70.

  The first arm 80 of the second linkage member 70 includes a central region 81 having a generally rectangular cross section that surrounds the axle 82. The end of the first arm 80 furthest from the airplane door forms a downwardly pointing finger 84. As will be described in more detail, fingers 84 compress pawl 42 during the door opening sequence to ensure that pawl 42 is not clogged or stuck in place by ice or other debris.

  The end region of the first arm 80 closer to the airplane door 14 (1) provides a second interconnect between the first arm 80 and the base plate 56, and (2) the evacuation system is released. When the airplane door 14 is opened, the pawl 42 is rotated downward so that the mooring bar 16 is released from the floor fitting, and (3) the evacuation system is released and the door is opened and closed. Dimensioned to interact with the jaws 58 of the base plate 56 so as to surround the cylindrical end portion 30 of the mooring bar 16 to secure the mooring bar 16 to the airplane door 14 when moving between them. Decided and placed.

To provide a second interconnection of the first arm 80 with the base plate 56, the first arm 80 includes two upwardly extending, substantially parallel, spaced flange regions 90 and 92. The end of bell crank 60, including groove 68, extends between flange regions 90 and 92. The pin or axle 98 passes through a suitably sized opening in the flange regions 90 and 92. Within the groove 68 is a cylindrical roller having a central passage for accommodating the axle 98. Roller 96 moves flange regions 90 and 92 (and thus first arm 80 of second linkage member 70) laterally along groove 68 during the operational sequence of the present invention discussed below.

  As can be seen from FIGS. 2-5, the flange region 90 of the first arm 80 extends downwardly at an angle away from the region of the flange 90 that receives the axle 82 to form a jaw 94. The jaw 94 is somewhat hooked in outer shape and is configured to partially surround the cylindrical portion 30 of the mooring bar 16 when the emergency evacuation system is released. As shown in FIG. 4 and described in more detail, the jaw 94 surrounds the portion of the cylindrical portion 30 facing the airplane door 14 and is moored when the emergency evacuation system is released. It acts in cooperation with the jaws 58 of the support fixture 20 to secure the rod 16 to the airplane door 14 (shown in FIGS. 3 and 4).

  The lower region of the flanges 90 and 92 is rounded to form a transition between the flange and the central region 81 of the first arm 80. Between the rounded lower portions of the flanges 90 and 92 is a cylindrical roller 88. As can be seen in FIG. 3, when the airplane door 14 is closed and the emergency evacuation system is released, the rounded edges of the cylindrical rollers 88 and flanges 90 and 92 are pawls 42. And the end of the pawl 42 facing the door 14 is rotated downward. The cylindrical portion 30 of the mooring bar 16 is moved by moving the pawl 42 to this rotated position when the evacuation system is released and the airplane door is opened in the manner shown in FIG. 4 and described in detail hereinafter. It becomes possible to move from the recess 40 of the floor fixture.

  The interlocking device, generally designated by reference numeral 100 in FIG. 2, prevents the operation of the present invention in such a manner that the mooring bar 16 is released when the emergency evacuation system is released and the airplane door 14 is open. Without such an interlock, it is possible to rotate the door handle 24 to the ready-to-operate position, thereby releasing the mooring bar 16 and dropping it downward from the lower edge of the door 14. It will be.

  In the configuration shown in FIGS. 2 to 6, the interlocking portion 100 is attached to the lower corner region of the base plate 56 closest to the door 14. The bell crank 102 located adjacent to the flat surface 57 of the base plate 56 includes an engaging arm 104 extending upward. The drive arm 106 forms an obtuse angle with the engagement arm 104 and points upwards away from the airplane door 14. The pin 110 passes through the portion of the bell crank 102 that extends between the engagement arm 104 and the drive arm 106 so that the bell crank 102 can rotate about a rotation axis that is parallel to the longitudinal axis of the anchoring bar 16.

  At the upper end of the engagement arm 104 is a finger 112 that extends inwardly toward the groove 68 of the bell crank 60. A torsion spring 118 between the interlocking bell crank 102 and the flat surface 57 of the base plate 56 surrounds the periphery of the pin 110 to bias the bell crank 102 to the position shown in FIG. In this position, the engagement arm 104 is moved in the direction of the bell crank 60 and the fingers 112 of the engagement arm 104 prevent the bell crank 60 from rotating counterclockwise.

The end region of the drive arm 106 is bent or otherwise formed to project at a right angle away from the bell crank 102. On the perpendicularly projecting portion of the drive arm 106 is an adjustable stop 116 (shown as a bolt in FIGS. 2-6). When the door is closed, as shown in FIGS. 3 and 5, the stop 116 presses the upper surface of the finger-like region 54 of the floor fixture 18. In the preferred embodiment of the invention, the bolt heads that form the stops 116 are coated with a flexible material that will dissipate impact forces and reduce wear. When the stop 116 is pressed against the floor fixture 18, the bell crank 102 of the interlocking device 100 is in a position where the interlocking arm 66 of the grooved bell crank 60 swings upward through the fingers 112 of the bell crank 102. Rotated. As described in more detail, when the door is closed and the mechanism handle 24 is moved from the system release position to the system ready state, the bell crank 102 rotates in the manner described above, causing the mooring bar 16 to move to the door. 14 is released.

  When the evacuation system is released and the door 14 is not latched, the support fixture 20 is positioned on the floor fixture 18 as shown in FIG. Accordingly, the stop 116 no longer compresses the finger 54 of the floor fixture 18 and the torsion spring 118 moves the engagement arm 104 of the bell crank 102 to abut the interlocking arm 66 of the grooved bell crank 60. As a result, the finger 112 of the engaging arm 104 of the bell crank 102 of the interlocking portion is positioned below the interlocking arm 66 of the grooved bell crank 60, whereby the slide evacuation system accidentally becomes ready for operation. The result mooring bar 16 is prevented from being inadvertently released.

  The present invention can be better understood by considering the operation of the invention during normal departure and arrival of an airplane and the operation of the invention during an emergency evacuation.

  In preparation for the departure of the airplane, the airplane door 14 is swung to its closed position. As seen in FIG. 4 which shows the door closed but not yet latched, the circular end portion 30 of the mooring bar 16 is between the jaws 58 and 94 of the support fixture 20. The mooring bar 16 is held at the bottom of the door 14 by being grasped firmly. The fingers 112 of the bell crank 106 extend below the upper end of the bell crank 60, thereby rotating the bell crank 60 to release the anchor bar 16 from securing between the jaws 58 and 94. The handle 24 (not shown in FIG. 4) of the door 14 is prevented from rotating. When the system is in this state, the pawl 42 of the floor fixture 18 is offset so that its upper end extends across the opening of the recess 40. When the door 14 is latched, the door moves downward and moves each base plate 56 to abut the associated floor fixture 18. As shown in FIG. 3, by latching the airplane door 14, the circular end portion 30 of the mooring bar 16 is placed in the recess 40 of the floor fixture 18. At this point in the sequence, the mooring bar 16 remains secured to the bottom of the door by the jaws 58 and 94 of the base plate 56. Further, as the airplane door 14 moves to its lower, latched position, the rollers 88 and the rounded corners 86 of the first arm 80 of the base plate 56 cause the floor fixture 18 to It can be noted that the upper end of the pawl 42 is pushed downward. This causes the upper end of the pawl 42 to rotate downward so that it does not extend across the opening in the recess 40 of the base plate 56. In addition, as the door 14 moves downward, the end of the stop 116 of the bell crank 102 contacts the upwardly extending finger-like portion 54 of the floor fixture 18. When the door is in the fully lower and latched position of FIG. 3, the bell crank 102 rotates to a position where the upper end of the bell crank 60 passes below the fingers 112 of the bell crank 102. In the state, the stop 116 presses the finger-like protrusion 54 of the base plate 56.

The next step in the operating sequence is to prepare the emergency evacuation system for takeoff. To prepare the system for operation, the handle 24 for the mechanism 10 causes the push-pull cable 26 to rotate the bell crank 60 in a clockwise direction (relative to the orientation shown in FIGS. 2-6). Rotated to position. With particular reference to FIG. 5, the rotation of the bell crank 60 causes a corresponding rotation of the first arm 80 and the jaw 94 rotates away from the circular end 30 of the mooring bar 16. In addition, the rotation of the first arm 80 causes the roller 88 and the rounded corner of the first arm 80 to move upward away from the end of the crimp 42. This releases the pawl 42, which is offset by an amount that extends across the opening in the recess 40 by an amount sufficient to prevent the circular end portion 30 of the anchor bar from moving out of the recess 40. Return to the given position. To provide the crew member with a positive tactile indication that puts the system in a ready state, the upper edge of the bell crank 60 contacts the stop mechanism when the bell crank 60 rotates to the ready state. As best seen in FIG. 2, the stop mechanism includes a flange 120 that projects outwardly at a right angle from a position above the bell crank 60 on the surface of the base plate 56. A bolt 116 or similar adjustable stop device extends upward through the flange 120. When the bell crank 60 swings to the ready position, the upper edge of the bell crank is pressed against the head of the bolt 116 and is connected by a solid member instead of the somewhat flexible push-pull cable 26. A “bottom-out” effect that mimics the operation of the handle structure.

  When the airplane arrives at the destination as usual, the crew releases the system by rotating the handle 24 of the mechanism 10 to the release position. As a result, the bell crank 60 rotates to the already described position shown in FIG. When the bell crank 60 swings to the release position, the upper side of the upper end of the bell crank 60 contacts the stop mechanism, giving a tactile indication that the handle 24 has reached the release position. The stop mechanism that provides the tactile indication is similar in configuration to the stop mechanism described above to indicate that the handle 24 is in the system ready state. Specifically, a flange 122 protruding at a right angle extends from a position above the upper end of the bell crank 60 in the base plate 56. An adjustable stop 116 (which is a bolt in the structure shown) extends upward through the flange 122.

  With the system in the unlocked state, when the crew member unlatches the airplane door 14, the door 14 moves upward toward the position described in connection with FIG. When the door moves to the position shown in FIG. 4, the bell crank 102 can rotate (counterclockwise in FIGS. 3 and 4), so that the finger-like protrusion 112 of the bell crank 102 is at the upper end of the bell crank 60. The bell crank 60 is secured in a manner that extends below the section, thereby preventing the mechanism handle 24 from moving to the system ready state. As previously described in connection with FIG. 4, the circular end portion 30 of the anchoring bar 16 is circled and grasped by the jaws 58 and 94 of the support fixture 20. In addition, when the door 14 is moved upward, the pawl 42 returns to a biased position where its upper end extends across the opening of the recess 40 of the floor fixture 18. The mooring bar 16 will therefore be secured to the bottom of the door and the door will be opened without unfolding the escape slide.

  The operation of the present invention for deploying an emergency evacuation system can be understood in connection with FIGS. In particular, as already mentioned, FIG. 5 shows the situation where the airplane door is closed and latched and the invention is operated to activate the emergency evacuation system. In the ready state of operation, the cylindrical end portion 30 of the mooring bar 16 is in the recess 40 of the floor fixture 18. Each pawl 42 of the floor fixture 18 is biased to a position where its upper end extends over the opening to the recess 40 so that the cylindrical end portion 30 (and thus the mooring bar 16) is the floor of the airplane. Fixed to.

  As shown in FIG. 6, when the door 14 is latched, the door moves upward to disengage the support bracket 20 from the floor fixture 18, and then the mooring bar 16 and the base of the escape slide are positioned on the floor. The door 14 can swing to an open position while being secured to the bottom. When the door opens, the emergency evacuation system is activated to quickly inflate the escape slide so that the escape slide extends downward for passengers and crew.

  The downwardly facing fingers 84 of the second linkage member 70 serve to ensure that the end of the pawl 42 closer to the anchor bar 16 does not freeze in the unlocked position shown in FIG. More specifically, due to ice formation or other reasons, the pawl 42 may freeze into the unlocked position despite being misaligned to return to the locked position. Thus, even if the support fixture 20 moves away from the pawl 42 as shown in FIG. 4, the pawl will remain in the unlocked position. This is a problem when the mechanism 10 places the slide evacuation system in a ready state of operation because the floor fixture 18 will not properly secure the mooring bar 16.

  Thus, when the mechanism 10 prepares the slide evacuation system for operation, the finger 84 rotates to a lower position as shown in FIGS. Thus, when the door 14 is locked as shown in FIG. 5, the fingers 84 press against the end of the pawl 42 far from the anchor bar 16 and push the pawl back into the locked position.

  While various configurations may be used in connection with the present invention to deploy the emergency escape escape slide, the presently preferred embodiment of the present invention is that the mechanism handle 24 is in the ready position and the inner door handle. An electrical interlocking system is used that allows activation only when 21 is in its open position. This preferred configuration is shown schematically in FIG. In the configuration of FIG. 7, a battery pack 132 or other power source is connected to an electrical squib 146 attached to a pneumatic reservoir 148. When current is supplied to the electrical squib 146, the explosion charge is ignited, driving the penetrator through the divider in the pneumatic reservoir 148. The air pressure provided by the air pressure reservoir 148 activates the air pressure resistor 150 to quickly open the door 14 and expands the escape slide by a second air pressure reservoir (not shown).

  In the configuration of FIG. 7, the escape slide can be deployed when the mechanism handle 24 is in the system ready state and the inner door handle 21 is in the open position. In particular, the switch 124 is mechanically coupled to the handle 24 (or any other element of the present invention) so that the switch 124 is closed (conducted) only when the system is ready for operation. In a similar manner, the serially connected switch 126 is closed (conducted) only when the airplane's inner door handle 21 is in its open state.

  The battery pack 132 includes a rechargeable battery 134 such as a nickel-cadmium battery. In addition, the battery pack 132 includes a battery charger 136 having a trickle charger 138 and a fast charger 140. Fast charger 140 charges battery 134 quickly while trickle charger 138 maintains a fully charged state of the battery. Power from the airplane is supplied in parallel to trickle charger 138 and fast charger 140. Trickle charger 138 and fast charger 140 then supply power in parallel with battery 134.

  Test switch 142 and safety switch 144 are included with battery pack 132. The safety switch 144 is for cutting off the electric power to the squib 146 to prevent unintended activation of the squib during maintenance. If the test switch 142 is not pressed, it remains open. When the crew member presses the test switch 144, it couples a light source (not shown) to the conventional circuit, which is that the trickle charger and / or fast charger is energizing the battery 134 and the battery charge is predetermined If it is above the level, illuminate the light source.

  While the preferred embodiment of the invention has been illustrated and described, various changes can be made therein without departing from the spirit and scope of the invention. As an illustrative, non-limiting example, push-pull cable 26 may be replaced with a linking member, such as a rod, and rechargeable battery 132 eliminates the need for battery charger 136, a long-lasting non-recharge. It may be of the formula. In view of these and other alternatives, substitutions and modifications that may be made by those skilled in the art, the scope of the patent granted therein is intended to be limited only by the definition of the appended claims. .

1 is a perspective view of a preferred embodiment of an actuation preparation and release mechanism constructed in accordance with the present invention and connected to an airplane door and floor. FIG. FIG. 6 is an enlarged perspective view of one end of the actuation preparation and release mechanism in a partially disassembled configuration. FIG. 2 is a view of one end of the actuation preparation and release mechanism of FIG. 1 shown with the door closed and locked, and the actuation preparation and release mechanism shown in the released state. FIG. 4 shows the mechanism of FIG. 3 with the door closed but shown unlocked and the actuation ready and release mechanism shown in the released state. FIG. 4 shows the mechanism shown in FIG. 3 with the door closed and locked, and the actuation ready and release mechanism being operated to bring the emergency slide evacuation system into a ready to run state. FIG. 4 shows the mechanism shown in FIG. 3 with the door shown closed but unlocked and the actuation ready and release mechanism shown in the actuation ready state. FIG. 2 is a schematic diagram of an electrical system for operation of an emergency evacuation system using the actuation preparation and release mechanism shown in FIG. 1.

Explanation of symbols

  18 floor fitting, 20 support fitting, 24 handle, 32 base, 42 pawl, 58 jaw, 60 first linkage member, 70 second linkage member, 80 arm, 94 jaw, 124 switch, 126 Switch, 132 Battery pack, 146 Fire detonator.

Claims (2)

An interlocking device for use with an aircraft emergency evacuation system, the system being attached to an aircraft fuselage under an airplane slide, an escape slide with a mooring rod connected to one end thereof, A floor fixture for holding the mooring bar; and a mechanism for releasing the system into a ready state of operation, the mechanism being attached to an aircraft door and including opposing jaws; A jaw position for releasing the system; Movable between an open position for releasing the mooring rod to be held by the floor fixture, the mechanism being in a position ready for operation, wherein the mechanism includes the gripping position and the open position. Before Includes linkage member for moving the jaws, the interlocking device comprises a bell crank was attached to the mechanism, the bell crank includes first and second arm, unlock the lock position In the locked position, the first arm engages with the linkage member of the mechanism for preparation and release, and the jaw moves from the gripping position to the open position. In the unlocked position, the first arm is released from the linkage member , and the bell crank includes a torsion spring that biases the bell crank to stay in the locked position. Interlocking device for use with the system.   When the door is closed and locked, the second arm comes into contact with the floor fixture, and by the contact, a pushing force is applied to the second arm, which locks the bell crank. The interlocking device according to claim 1, wherein the interlocking device is rotated to a release position.

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